183 10 PR Campaign: Proportion, Prioritization, and Precaution The impressive safety record of the nuclear industry (including but not limited to medical uses of radiation and nuclear power) is prima facie evidence that the current system of radiation protection works. Regulatory limits, particularly for the public, are set well below observable risk levels. Radiation doses encountered in occupa- tional settings under normal operating conditions are also tiny fractions of levels known to produce acute injury. Risks of radiogenic cancer are so low that they are very difficult to measure, if they can be measured at all. Despite the stellar worker and public safety record, the radiation protection framework is complex and con- fusing, promotes public fear of low doses of radiation, and is increasingly expensive. A risk-based system of protection is difficult to defend because of large uncertainties in risk. Communicating risk information is challenging because the public has difficulty understanding small risks. The current radiation protection framework needs restructuring to simplify pro- tection and improve public communication. Central to reorganization is the switch from a risk-based to a dose-based system of protection. Dose proportion is an effective communication tool, and quantifying dose reduction is a meaningful metric for protection because dose can be measured directly. Further radiological protection must focus on radiological risks within the broader context of competing risks. Prioritization of risk is the key to efficient public health protection. Prioritization does not marginalize management of small risks but recognizes that the greatest gains in health protection are realized by managing large risks. The public continues to push towards a zero risk tolerance in which the balanced cost-benefit approach of the as low as reasonably achievable (ALARA) philosophy is replaced by a precautionary approach of better safe than sorry. The view is that risks should be avoided at all costs. Certainly some precaution is prudent and necessary in risk management given that scientific certainty is unattainable. But in radiation safety, strict precaution is not required. Sufficient information about health risks is known at radiation levels found in occupational and environmental settings. Pr oportion, prioritization, and precaution is the blueprint for a new radiological protection system. This PR campaign leads to a more efficient system that will maintain the high level of protection currently enjoyed in the nuclear sector but is easier to communicate, less complex, and more cost effective. 7977_C010.fm Page 183 Wednesday, September 13, 2006 10:21 AM © 2007 by Taylor & Francis Group, LLC 184 Radiation Risks in Perspective PROPORTION quantification at low dose. The problems associated with assessing very uncertain risk using predictive theories like LNT are avoided by using dose proportions. Quantification of small risks is a problem because the science underlying the risk- assessment process is uncertain. The public has great difficulty comprehending very small probabilities. Furthermore, the public mistakenly concludes that theory- derived risks are “real” when, in fact, they are nothing more than “speculates.” Dose is preferable to risk as an indicator of health detriment because it can be measured directly. Risk is inherently more uncertain than dose because risk is a dose derivative. However, even dose measurements must be interpreted cautiously because of new scientific understanding suggesting that very small doses may not relate to health detriment. The dose proportion is the ratio of the measured or calculated dose to a reference dose. The dose proportion is dimensionless and thus independent of specific dose units. Dealing with proportions (rather than risk probabilities) is a more effective way of communication because the numbers have meaning, provided that the ref- erence dose is clearly explained. The dose proportion should also include some expression of variability and uncertainty. Variability has to do with changes in the value due to natural tendencies or differences in the environment (such as geograph- ical differences in natural background radiation levels); uncertainty has to do with the statistical or random errors in measurement. Dose proportions for selected environmental, occupational, unplanned (accident), 1 considerably. A dose proportion equivalent to unity means that the dose received is equal to one year’s worth of natural background radiation (about 1 mSv per year TABLE 10.1 Dose Proportions for Selected Environmental, Occupational, and Accident Exposures Exposure Dose Proportion X-ray security screening 0.0003 Transcontinental Airline flight 0.1–0.5 Chernobyl accident 14 Hypothetical nuclear terrorism incident 3–30 Nuclear worker average annual dose 20 Annual exposure on international space station 170 Sources: Values in the table were calculated from dose estimates provided in: National Research Council, Airline Passenger Security Screening: New Technologies and Implementation Issues, National Academy Press, Washington, DC, 1996; Brenner, D.J. et al., Cancer risks attributable to low doses of ionizing radiation: Assessing what we really know, Proceedings of the National Academy of Sciences, 100, 13761, 2003; Cardis, E. et al., Risk of cancer after low doses of ionizing radiation: retrospective cohort study in 15 countries, British Medical Journal, 331, 77, 2005. 7977_C010.fm Page 184 Wednesday, September 13, 2006 10:21 AM © 2007 by Taylor & Francis Group, LLC and medical exposure scenarios are listed in Tables 10.1 and 10.2. Values can vary The “dose proportion” concept was introduced in Chapter 7 as an alternative to risk PR Campaign: Proportion, Prioritization, and Precaution 185 excluding contributions from radon gas). Dose proportions less than or more than unity represent submultiples or multiples of the reference natural background radia- with deterministic effects such as skin reddening or bone marrow depression. Certain high dose medical procedures such as radiotherapy for cancer produce acute effects (Table 10.2). Dose proportions in excess of about 500 would be needed to observe deterministic effects. Risks of cancer are increased for dose proportions greater than 100. Radiogenic cancer risks have been difficult to observe for dose proportions below 100, so any risk estimates must be viewed with considerable caution. For nonmedical exposures, dose proportions range over 6 orders of magnitude (Table 10.1). Environmental exposures are routinely very small. Airline passengers must undergo security screening at airports, and the x-ray dose is a tiny fraction of natural background radiation levels. Passengers on a round trip airline flight from New York to London are exposed to a small additional dose of radiation (about 0.1 to 0.5 mSv) due to increased cosmic ray exposure at high altitude. Accidental and occupational exposures by their nature are highly variable. The dose proportion for the Chernobyl accident reflects a calculated average whole body dose of 14 mSv over a 70-year period to 500,000 individuals in rural Ukraine in the vicinity of the accident site. Some Chernobyl victims received doses much higher or lower than the average depending on their location relative to the plant. The dose proportion for the hypothetical terrorist event (Table 10.1) is determined theoretically and is highly uncertain. It is based on computer generated dose distributions over a 20-block radius from a hypothetical nuclear terrorism incident involving dispersal of radioactive cesium from a radiological dispersal device or “dirty bomb” detonated in a large urban environment. Workers in the nuclear industries may be exposed to large doses unless proper controls are in place. In several studies of health effects in nuclear workers, average doses were estimated to be about 20 mSv. Exposures to workers on the international space station are very high because of intense cosmic radiation from outer space. On Earth the atmosphere filters out most of the cosmic rays. TABLE 10.2 Dose Proportions for Selected Medical Exposures Exposure Dose Proportion Chest x-ray 0.2 Mammogram 3 Pediatric CT 25 Fluoroscopy (1 minute) < 100 Cardiac catheterization 100 Radiation therapy for cancer > 30,000 Sources: Values in the tables were calculated from dose estimates provided in: National Council on Radiation Protection and Measurements (NCRP), Exposure of the U.S. Population from Diagnostic Medical Radiation, NCRP Report No. 100, NCRP, Bethesda, MD, 1989; Brenner, D.J. et al., Cancer risks attributable to low doses of ionizing radiation: Assessing what we really know, Proceedings of the National Academy of Sciences, 100, 13761, 2003. 7977_C010.fm Page 185 Wednesday, September 13, 2006 10:21 AM © 2007 by Taylor & Francis Group, LLC tion level respectively. None of the dose proportions listed in Table 10.1 is associated 186 Radiation Risks in Perspective Medical and dental x-rays are the largest anthropogenic source of radiation exposure and account for about 18% of the total annual radiation exposure to the U.S. population. 2 Diagnostic studies to obtain important medical imaging informa- tion usually involve small doses, but in some studies the dose can be quite high considered negligible in the context of expected medical benefits. A chest x-ray results in a skin entrance dose of about 0.2 mSv. 3 A screening mammogram results in a breast dose of about 3 mSv. These doses are very small compared to doses received by children during computerized tomography (CT) scans of the abdomen. Cardiac catheterization is an interventional procedure that can result in large doses to the patient in order to assess patency of coronary arteries. Unlike other applications of radiation in medicine, very large doses are needed in cancer therapy to kill cancer cells. Doses in radiation therapy and in complicated interventional cases are large enough to produce deterministic effects. A scale of dose proportions can be readily calibrated by comparing values to specific benchmarks such as dose limits and doses known to produce stochastic and deterministic effects. Benchmarks do not assume any particular dose response but are used to put measured dose proportions in perspective. In the context of the dose able annual radiation exposure to workers is 50; a dose proportion of 100 represents the minimum dose associated with elevated cancer risk; the threshold for determin- istic effects is represented by a dose proportion of 500. There is little epidemiological evidence in support of statistically significant cancer risks for dose proportions up to 100. Environmental, occupational, and most diagnostic medical exposures are in this range. Risks are highly uncertain, and the shape of the dose-response function is unclear. Accordingly, dose proportions below 100 must be interpreted with caution. Dose proportions are important in communicating health risks to the public. Risks are interpreted differently by experts and by the public. Scientists, engineers, and other experts prefer to use quantitative approaches. However, the public is generally ill prepared to deal with risk numbers, particularly if they are expressed as percentages or ratios that can be easily misinterpreted. Accordingly, quantification of small risks should be avoided. Qualitative expressions are more meaningful (e.g., “The risk is considered insignificant” or “The risk is so small that health impacts are considered unlikely”). Use of qualitative descriptions (e.g., high, moderate, low) or other semi- quantitative approaches can be effective communication tools. Use of qualitative expressions of health detriment for dose proportions up to 100 is preferred because it is a scientifically defensible approach. Because of the large uncertainties in small risks, quantification has little meaning and may reflect a degree of confidence not supportable by the data. The public is more likely to understand qualitative expressions of risk even though quantifying risk would appear to be the superior approach. Dose proportions may be particularly useful in the informed consent process to ensure that risks of medical radiation exposure are stated accurately and in language understandable to the patient or research subject. Patients and research subjects should understand the risks before consenting to undergo medical diagnostic proce- dures or therapy. Dose proportions place radiation doses in perspective. For example, 7977_C010.fm Page 186 Wednesday, September 13, 2006 10:21 AM © 2007 by Taylor & Francis Group, LLC (Table 10.2). Cancer risks from diagnostic studies are too small to measure and are proportions listed in Table 10.1, dose proportion representing the maximum allow- PR Campaign: Proportion, Prioritization, and Precaution 187 assume a patient undergoes a mammogram in which the midline breast dose is 3 statement may be included in the informed consent form to help the patient better understand the significance of the dose: 4 The amount of radiation received in this procedure is equivalent to the amount of naturally occurring background radiation that all individuals in the United States receive in a three-year period. The risk from an exposure of this magnitude is generally considered negligible. In cases when radiation doses are high (e.g., doses greater than 200 mSv), quantitative expressions of risk are warranted as long as uncertainties in risk esti- mates are provided. Risks of radiogenic cancer have been observed directly for doses in excess of 200 mSv, and LNT theory provides reasonable and conservative esti- mates of risk. Qualitative and quantitative descriptions of risk carry different but equally valuable perspectives. Each approach has its own biases and limitations. PRIORITIZATION The primary goal of public health protection is the control of environmental factors known to cause disease. The major risk factors compromising U.S. public health are well known. Smoking, diet, and lack of exercise are now recognized as the major causes of death in the U.S. Cigarette smoking is responsible for 30% of cancer deaths and is also a major contributor to cardiovascular mortality. Obesity is increas- ing at an alarming rate, especially in developed countries, with major adverse consequences for human health. The U.S. Centers for Disease Control and Prevention (CDC) reports that from 1988–1994, 60% of adults in the U.S. were overweight or obese, a figure that rose to 65% in 1999 to 2000. Obesity is considered to be a contributing factor to chronic diseases such as heart disease, cancer, and diabetes. According to CDC, physical inactivity now ranks as the number three cause of death in the U.S. Lack of exercise plays a role in many chronic diseases that lead to early mortality. Control of these risk factors is challenging. Any serious risk-management initiative will depend on individual and community programs that focus on modi- fying personal behaviors and public education through government, industry, and commercial messages. Numerous epidemiological studies on geographical and temporal variations in cancer incidence, as well as studies of migrant populations and their descendants that acquire the pattern of cancer risk of their new country, indicate that over 80% of cancer deaths in Western industrial countries can be attributed to factors such as tobacco, alcohol, diet, infections, and occupational exposures. Diet and tobacco together account for about two-thirds of cancer deaths. In a recent compilation of data, it was estimated that about 75% of all cancer deaths in smokers and 50% of all cancer deaths in nonsmokers in the U.S. could be avoided by elimination of these risk factors. 5 “Cancer” represents over 100 different diseases. For some cancers environmental risk factors are well known (e.g., smoking and lung cancer); for other cancers 7977_C010.fm Page 187 Wednesday, September 13, 2006 10:21 AM © 2007 by Taylor & Francis Group, LLC mSv (equivalent to a dose proportion of 3 as shown in Table 10.1). The following 188 Radiation Risks in Perspective environmental causation is poorly understood (e.g., prostate cancer). Known human carcinogens do not increase cancer risks uniformly. Whole-body exposure to ionizing radiation increases cancer risks in some tissues (e.g., thyroid gland) but has no effect on other tissues (e.g., prostate gland). Cigarette smoking clearly increases cancer of the lung and upper aero-digestive tract but is not known to affect certain other tissues such as the thyroid gland or brain. Which cancer risk factors are important and which ones are insignificant? How are risk factors perceived, and what does perception have to do with risk prioritiza- tion? Quantitative measures of risk are not necessarily congruent with public per- ceptions. More than one-third of Americans believe Acquired Immune Deficiency Syndrome (AIDS) is the most urgent health problem facing the world today, ranking it second to cancer; yet concern about AIDS has been decreasing. Smoking is recognized as the single most important preventable risk factor. But tobacco-related cancers (e.g., lung cancer) do not receive the scientific support that other less lethal cancers do (breast, prostate). Research funding seems out of sync with mortality risks. 6 Unfortunately, we fear the wrong things and spend money to protect ourselves from minor risks. We allocate limited resources to manage risks that pose little, if any, health concerns and ignore larger risks that have a significant health impact. The prioritization problem is illustrated in the U.S. Environmental Protection Agency’s (EPA) recent tightening of the arsenic standard for drinking water. The EPA revised the current drinking water standard for arsenic from 50 parts per billion (ppb) to 10 ppb. 7 The agency claims that the more restrictive limit will provide additional health protection against cancer and other health problems, including cardiovascular disease and diabetes. To meet the new arsenic standard, the public is spending millions of dollars on new water mains and water treatment plants. Water rates across the country have increased significantly to meet the new EPA guidelines. But there is little evidence that reducing the standard from 50 ppb to 10 ppb has any direct benefit on the public health. In the meantime efforts to curb poor air quality in large urban environments remain seriously underfunded. Poor air quality has been clearly linked to ill health. Small risks should not be ignored but must be placed in perspective. It makes little sense to allocate significant resources to management of risks that have little public health impact when larger, more significant risks remain poorly controlled. The key word is “significant.” What may be a minor risk to some may be considered significant by others. Small individual risks should be managed if appropriate control technologies are available with due consideration for competing risks and cost- benefit analysis. This book has promoted the idea that analyzing and discussing individual risks without regard to the presence of other risks is inappropriate. Often risks that may appear to be important when considered in isolation may become less significant when compared to other risks in the environmental or occupational setting. An individual risk cannot be evaluated in isolation but only in relation to, and with, other risks. To understand what risk (and dose) means requires that it be placed in appropriate context, including comparisons of dose and comparisons of health out- comes. 7977_C010.fm Page 188 Wednesday, September 13, 2006 10:21 AM © 2007 by Taylor & Francis Group, LLC PR Campaign: Proportion, Prioritization, and Precaution 189 The fact that most radiological risks are small and cannot be reliably measured does not minimize their importance. We should manage such risks given the avail- ability of resources. Major public health gains in the cancer wars are achieved by focusing on diet and smoking. Controlling radiological risks is a small battle but nevertheless worth fighting because we have the technological capabilities of doing so. If we can avoid exposure, we should do so. Individuals who might be exposed to radiation or other carcinogens should be protected. Although a utilitarian philos- ophy is the most cost-effective approach to public health protection, ideally no one should be left unprotected. Of course, resources are severely limited even in the wealthiest countries, and unfortunately, some people cannot be protected to the extent that we would like. Public officials and risk managers are left with the difficult task of deciding who can be adequately protected and who cannot. PRECAUTION The precautionary principle is an extremist approach to risk management that advo- cates zero risk tolerance. In radiological protection there is no justification for implementation of a precautionary risk-management approach. 8 As discussed in the vehicle for introducing arbitrary public policy and regulations. Zero risk tolerance imposes unreasonable restrictions on technologies such that little or no progress is possible. Holding up technological progress because of concerns about proving safety beyond a reasonable doubt is a way of guaranteeing that advances will be significantly and unjustifiably hindered. The precautionary principle is set within a consequential framework in which disproportionate weight is placed on probabilities, however small, of disastrous outcomes. Rather than a simple net utility rule (i.e., balancing risk against benefit), the precautionary principle proposes that even if there is a favorable weighing of costs against benefits the technology should nevertheless be rejected if even very small risks are large enough. The cell phone debate in the U.K. clearly illustrated this. Recourse to the precautionary principle is used by decision makers to cope with public fears when technological risks are considered serious and cannot be excluded. The precautionary principle sounds relatively innocuous on its face, giving regulators broad authority to err on the side of safety by adopting temporary and proportionate measures to prevent any serious and irreversible harm to human health or the environment. In practice, however, the precautionary principle is creating a wave of absurd and arbitrary risk decisions across Europe since the European Union adopted the principle into its laws in 1992. 9 Further, it is unclear whether implementation of the precautionary principle actually accomplishes what is intended. The objective of the principle is to reassure the public by taking extreme protective actions by removal of or severe limitation of the technology. However, such actions may have the opposite effect by alarming the public. Precautionary action may be interpreted as recognition by authorities that the technological risk is serious and the public needs proportional protection. Whether the public feels reassured or alarmed by precautionary decisions will 7977_C010.fm Page 189 Wednesday, September 13, 2006 10:21 AM © 2007 by Taylor & Francis Group, LLC case study on cell phones (Chapter 9), the precautionary principle has become the 190 Radiation Risks in Perspective depend on the initial level of public concern, the extent of public consultation, and the level of trust between the public and authorities. 10 Precautionary approaches are reasonable for technologies in which activities or products are known to produce very serious risks and little benefit. The precautionary principle has an important role to play in cases such as global warming where potential consequences are severe and eliminating certain technologies would dimin- ish the risk. In this case eliminating technologies may avoid serious catastrophe. But there is little justification for a precautionary approach in the management of most technological risks. The precautionary principle avoids the rational analysis of weighing costs against benefits in decision making and can lead to potentially serious risk trade-offs and unintended consequences that may be more serious than the risks the precautionary principle was intended to avoid. The ban on dichloro-diphenyl-trichloroethane (DDT) in the 1960s is an example of how misapplication of the precautionary principle can lead to tragic consequences. DDT is a highly effective pesticide for the control of a variety of insects including mosquitoes and was a welcome substitute for toxic insecticides containing arsenic, mercury, or lead. DDT was introduced as a pesticide in the 1940s but was banned in the U.S. and other countries in the 1960s because of questions of safety. The DDT ban led to a dramatic increase in malaria because mosquito populations could no longer be effectively controlled. Experiences in Sri Lanka testify to DDT’s effectiveness. In the late 1940s, prior to the introduction of DDT, about 3 million cases of malaria were reported in Sri Lanka. After introduction of DDT in 1963, the number of malaria cases plummeted to fewer than 100. Malaria incidence remained low until the DDT ban was introduced in the late 1960s. By 1968 1 million new cases of malaria were reported and in 1969 the number of malaria cases reached 2.5 million, roughly the same number as pre-DDT levels. The decision to ban DDT was based in part on the belief that DDT is a human carcinogen. However, the weight of scientific evidence suggested otherwise; by 1970 the overwhelming scientific evidence was that DDT is both safe and effective. DDT saved lives, but unsubstantiated concerns about safety led to an unwarranted ban resulting in death and disease in millions of people. 11 On February 28, 2005, the French Parliament finalized amendments to its national Constitution to incorporate an Environmental Charter. Among other provi- sions, this charter mandates the application of the precautionary principle to all regulatory decisions in France. This action to enshrine the precautionary principle in its Constitution commits France to a path that will severely damage both the economy and public health of France and its trading partners. In its current form, the precautionary principle is not sustainable in the long run. If the principle has a future it must be reformulated to establish itself as an aspect of the rational management of risks. It is not designed to achieve zero risk, which everyone agrees cannot be achieved. Based on the Europe experience, the precau- tionary principle has shown itself to be a reckless, unreasonable, and irresponsible experiment. The recent actions of the French Parliament ensure that the current version of the precautionary principle will inflict a lot more harm and mischief around the world before it eventually and inevitably collapses upon itself. 12 The current system of radiological protection promotes the idea that any dose of radiation is potentially harmful. Coupled with the notion that even the tiniest 7977_C010.fm Page 190 Wednesday, September 13, 2006 10:21 AM © 2007 by Taylor & Francis Group, LLC PR Campaign: Proportion, Prioritization, and Precaution 191 amounts of radiation can be reliably detected, it is easy to understand how the public concludes that even the smallest measurable dose is dangerous. In the public’s view the goal of any risk-management system should be to clean up every radioactive atom whether natural or anthropogenic. A system of protection that promotes these ideas does a disservice to the public. Although the current framework adequately protects workers and the public, it is overly complex and fails to distinguish real from theoretical risks. The underlying theme in this PR campaign is simplicity. Simplicity focuses on identifying essential elements of a system of protection. Measurement and reduction in dose is the essence of a system of protection; risk cannot be measured at dose levels encountered in most environmental and occupational settings. Risk loses meaning when probabilities are very small and beyond everyday experiences; risk cannot be readily understood by the public. Simplicity focuses on similarities between comparable entities like anthropogenic and natural background radiation. The only property that distinguishes natural and anthropogenic radiation is its source. Ionizing radiations, regardless of its sources, interact with matter in the same way and produce the same spectrum of biological effects. It is this principle that makes dose comparison from natural and man-made exposures valuable as a way of putting dose into perspective. NOTES AND REFERENCES 1. Dose proportions were calculated using annual natural background radiation (exclud- ing contributions from radon gas) as the reference. Values shown will increase or decrease depending on use of other reference doses (see, for example, dose propor- tions for residential radon in Chapter 8). 2. National Research Council, Health Risks from Exposure to Low Levels of Ionizing Radiation, BEIR VII Report, National Academies Press, Washington, DC, 2005. 3. Medical doses are usually expressed as absorbed doses using units of gray (Gy) or mGy (1 Gy = 1000 mGy). For x-rays and gamma rays 1 Sv = 1 Gy. 4. For this example natural background radiation levels are assumed to be 1 mSv per year excluding contributions from radon. See Mossman, K.L., Radiation protection of human subjects in research protocols, in Mossman, K.L. and Mills, W.A. (Eds.), The Biological Basis of Radiation Protection Practice, Williams & Wilkins, Balti- more, MD, 1992, 255. 5. Luch, A., Nature and nurture — Lessons from chemical carcinogenesis, Nature Reviews Cancer, 5, 113, 2005. 6. Jaffe, H., Whatever happened to the U.S. AIDS epidemic?, Science , 305, 1243, August 27, 2004; Dennis, P.A., Disparities in cancer funding, Science, 305, 1401, September 3, 2004. 7. The Safe Drinking Water Act requires the EPA to revise the existing 50 parts per billion (ppb) standard for arsenic in drinking water. On January 22, 2001, the EPA adopted a new standard and public water systems must comply with the 10 ppb standard beginning January 23, 2006. See EPA, National Primary Drinking Water Regulations; Arsenic and Clarifications to Compliance and New Source Contaminants Monitoring, Federal Register , 66 (14), 6975, January 22, 2001. 7977_C010.fm Page 191 Wednesday, September 13, 2006 10:21 AM © 2007 by Taylor & Francis Group, LLC 192 Radiation Risks in Perspective 8. Mossman, K.L. and Marchant, G.E., Radiation protection and the precautionary principle, Risk: Health, Safety & Environment , 13, 137, 2002. 9. Marchant, G.E. and Mossman, K.L., Arbitrary and Capricious: The Precautionary Principle in the European Courts, AEI Press, Washington, DC, 2004. 10. Weidemann, P.M. and Schütz, H., The precautionary principle and risk perception: Experimental studies in the EMF area, Environmental Health Perspectives , 113, 402, April 2005. 11. The DDT ban occurred prior to the formal establishment of the precautionary prin- ciple. Nevertheless, the ban on DDT is a clear example of extreme precaution. See Ray, D.L., Trashing the Planet, Regnery Gateway, Washington, 1990; Whelan, E.M., Toxic Terror, Prometheus Books, New York, 1993. 12. Marchant, G.E. and Mossman, K.L., Please be careful: The spread of Europe’s precautionary principle could wreak havoc on economies, public health, and plain old common sense, Legal Times, XXVII (33), 58, August 15, 2005. 7977_C010.fm Page 192 Wednesday, September 13, 2006 10:21 AM © 2007 by Taylor & Francis Group, LLC [...]... characterized by increasing response with increasing dose Mutagen A chemical or physical agent that causes a permanent change in DNA (mutation) or causes an increase in the rate of mutational events Natural background radiation Radiation from natural sources including cosmic radiation from outer space, terrestrial radiation from naturally occurring radionuclides in the earth’s crust, and naturally occurring radionuclides... trade-off where different target and countervailing risks occur in the same population Risk trade-off Efforts to manage the target risk may lead to increases in other countervailing risks Risk transfer A type of risk trade-off where the target and countervailing risks are the same but occur in different populations Risk transformation A type of risk trade-off where different target and countervailing risks. .. management A process of analyzing, selecting, implementing, communicating, and evaluating strategies to reduce risks © 2007 by Taylor & Francis Group, LLC 7977_C011.fm Page 196 Tuesday, August 1, 2006 6:07 PM 196 Radiation Risks in Perspective: Assessment and Control of Exposure Risk offset A type of risk trade-off where the target and countervailing risks are the same and occur in the same population Risk... adopted in similar circumstances Cosmic radiation A component of the natural background radiation consisting of high-energy ionizing radiation from outer space Cost-benefit analysis An approach to risk management requiring that risks, benefits, and costs be quantified so that they may be weighed against each other Countervailing risk Unintended risk that may occur as a consequence of management of target risks. .. doses and inhibition or detrimental effects at high doses The dose response is nonmonotonic and is J-shaped or inverted U-shaped Hypothesis A hypothesis is a conjecture usually in the form of a question that is the basis for the design of experiments to test a theory Ionizing radiation Radiation of sufficient energy to dislodge electrons from atoms in the absorbing material Ionizing radiation includes... radionuclides deposited in the body by ingestion or inhalation Neutron An uncharged subatomic particle in the atomic nucleus Nondiscrimination principle Risk reduction measures should not be discriminatory in their application, and thus comparable situations should not be treated differently Precautionary principle An approach to risk management that requires foregoing, postponing, or otherwise limiting a product... the Japanese survivors of the atomic bombs The sample includes approximately 85,000 persons for whom detailed radiation dose and medical information are available Linear no-threshold dose response A monotonic dose-response curve that is linear without a dose threshold The slope of the dose-response curve is constant Meta-analysis The process of combining results from several epidemiologic studies that... by having the capacity to spread to other parts of the body through the process of metastasis There are more than 100 types of human cancer Carcinogen A biological, chemical, or physical agent that may cause cancer Collective dose A measure of population exposure obtained by summing exposures for all people in the exposed population Units: person-sievert, person-rad Consistency principle Risk-reduction... exposure to ionizing radiation divided by the mass absorbing the radiation Units: gray (Gy) Acceptable risk (or dose) A risk or dose judged to have an inconsequential level of harm or injury and that is therefore considered to be safe Adaptive response Exposure of cells or animals to a low dose of radiation induces protective mechanisms against detrimental effects of a subsequent radiation exposure... equivalent doses in all tissues and organs of the body weighted for sensitivity to radiation Units: sievert (Sv) Electromagnetic radiation Radiation propagated through space or matter by oscillating electric and magnetic waves Electromagnetic radiation travels at the speed of light in a vacuum Examples include gamma rays, x-rays, visible light, radiofrequency, and microwaves Types of electromagnetic radiation . shown in Table 10. 1). The following 188 Radiation Risks in Perspective environmental causation is poorly understood (e.g., prostate cancer). Known human carcinogens do not increase cancer risks. Natural background radiation Radiation from natural sources including cos- mic radiation from outer space, terrestrial radiation from naturally occur- ring radionuclides in the earth’s crust,. trade-off where different target and counter- vailing risks occur in the same population. Risk trade-off Efforts to manage the target risk may lead to increases in other countervailing risks.